Mass Flow Calculation in digitalYEWFLO Vortex Flow Meter
Yokogawa Technical Report English Edition Vol.53 No.2 (2010)
Mass Flow Calculation in digitalYEWFLO Vortex Flow Meter- Highly Accurate Mass Flow Calculation Using FieldMate FlowNavigator -
Takashi Kawano *1 Shinnosuke Yoshida *1
Yokogawa introduced the world’s first vortex flow meter for industrial use in the 1960s, which is now widely used for measuring liquid, gas, and steam. However, Yokogawa’s digitalYEWFLO vortex flow meter had limited functions in tracking pressure changes especially in the measurement of gas and steam, for which mass flow measurement is generally required, due to the use of the pressure value as a constant. The newly developed FieldMate FlowNavigator flow configuration software applying Field Device Tool/Device Type Manager (FDT/DTM) technology has made it possible to compensate density using a physical properties database. Combined with FOUNDATION Fieldbus type digital YEWFLO, it can accurately calculate mass flow. This report describes mass flow calculation in the FOUNDATION Fieldbus type digitalYEWFLO, and highly accurate calculation of the mass flow of natural gas by FlowNavigator with actual test data.
INTRODUCTION
Vortex f low meters have been appreciated by users as volume flow meters, which can, in principle, be applied
to any flow measurement of liquid, gas, or steam.Volume flow measurement is enough for substances with
small variations in density such as liquid. However, mass flow must generally be calculated for steam and gas because their volumes vary significantly depending on temperature and pressure.
Although the current digitalYEWFLO vortex f low meter (1) in the market is capable of calculating mass flow for liquid, gas and steam, it has limited functions in tracking the pressure changes of measured f luids and providing highly accurate mass flow calculations because it partially regards the pressure value as a constant.
We have developed FieldMate FlowNavigator f low configuration software that runs on the FieldMate Versatile Device Management Wizard (2) which utilizes the Field Device Tool/Device Type Manager (FDT/DTM) technology.
Combined with the FieldMate FlowNavigator, Yokogawa's FOUNDATION Fieldbus communication type digitalYEWFLO has resolved the disadvantages mentioned above. In addition, mass flow calculations can be set up interactively, resulting in significant improvement of user’s convenience. Figure 1 shows the external view of the digitalYEWFLO and the FlowNavigator medium.
Figure 1 External View of digitalYEWFLO and FlowNavigator Medium
Integral type vortex flow meter
FlowNavigator medium
*1 Field Instruments Business Center, Industrial Automation Business Headquarters
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Mass Flow Calculation in digitalYEWFLO Vortex Flow Meter
Yokogawa Technical Report English Edition Vol.53 No.2 (2010)
FEATURES OF MASS FLOW CALCULATION BY THE FLOWNAVIGATOR
Yokogawa's FOUNDATION Fieldbus communication type digitalYEWFLO is capable of providing various mass flow calculations as listed below by configuring it using the information required for mass f low calculation through the FlowNavigator.
� Highly accurate mass flow calculation for general gases, natural gases, and general liquids (accuracy ≤ 1.1% at 35 m/s for natural gas)
� Mass flow calculation for custom fluids of users � Interactive configuration for conventional mass f low calculation for saturated steam and volume flow calculation under standard conditions using Boyle’s Law and Charles’ Law
T he FOU N DAT ION Fieldbus com mu nicat ion t y pe digitalYEWFLO can output mass f low rate responding to the varying conditions of the measured f luid by retrieving temperature and pressure data via the fieldbus.
SYSTEM CONFIGURATION
Overall configurationFigure 2 shows a system configuration example where the
FlowNavigator is used with a vortex flow meter and pressure transmitter to provide highly accurate mass flow measurement of general or natural gas.
Figure 2 System Configuration Example
Since the multivariable type digitalYEWFLO maintains f luid temperature in addition to volume f low rate, it can calculate mass flow rate by retrieving the pressure value from the pressure transmitter via the fieldbus communication. Data required for measurement, including fluid conditions and unit of mass flow, are set in the FlowNavigator on the PC. Among these data, the density compensation coefficients used for density calculation are downloaded to the digitalYEWFLO via f ieldbus communication. The digitalYEWFLO uses
downloaded parameters, including density compensation coefficients, to perform mass flow calculation.
A formula of density compensation for calculating the mass flow rate of gas is shown below. The digitalYEWFLO performs density compensation calculation using polynomial approximation to obtain highly accurate mass flow rate.
Function block configuration of digitalYEWFLOFigure 3 shows the conf iguration of the function
blocks (FB) of the FOUNDATION Fieldbus communication type digitalYEWFLO which performs the mass f low calculation.
Figure 3 FB Configuration Performing Mass Flow Calculation
Eight FBs are implemented in the digitalYEWFLO. The output from the AI2 (Analog Input 2) FB is temperature, and the output from the AI3 (Analog Input 3) FB is volume flow rate. Both output, together with the pressure measurement from the external pressure transmitter, are connected to INs of the AR (Arithmetic) FB. The AR FB offers extended calculation functions to enable various mass flow calculations as summarized in Table 1.
Configuration of FieldMate FlowNavigatorFigure 4 shows the configuration of the FieldMate
F l owN a v i g a t o r . T h e F l owN a v i g a t o r r u n s o n t h e FieldMate, and it comprises programs and resources. The programs include two f low rate calculation programs, DYFMVTool for the digitalYEWFLO vortex flow meter and EJXMVTool for the EJX series differential pressure/pressure
DCS
JunctionBox
Pressure transmitterEJX510
digitalYEWFLODYF FF
FOUNDATION Fieldbus
GasSteamLiquid
Download
PCFlowNavigator
• Pressure information
• Volume flow information• Temperature information
• Mass flow• Volume flow• Temperature
rf = Kr0 + Kr1 × (1/ Tf) + Kr2 × (1/ Tf)2
+ Kr3 × Pf + Kr4 × (1/ Tf) × Pf + Kr5 × (1/ Tf)2 × Pf
+ Kr6 × Pf 2 + Kr7 × (1/ Tf) × Pf
2 + Kr8 × (1/ Tf)2 × Pf 2
+ Kr9 × Pf 3 + Kr10 × (1/ Tf) × Pf
3 + Kr11 × (1/ Tf)2 × Pf 3
M = rf × Qf
rf : Fluid density after compensation [kg/m3]Krn : Density compensation coefficient (n = 0 - 11)Tf : Fluid temperature [K]Pf : Fluid pressure [kPa abs]M : Mass flow rate measured by digitalYEWFLO [kg/h]Qf : Volume flow rate measured by digitalYEWFLO [m3/h]
Arithmetic Function Block
IN_2
IN_1
IN <Extended part>Calculation types: 32-38
Density compensation
calculation
Mass flowcalculation OUT
AI3-Volume flow
digitalYEWFLO
(Built-in thermometer) OUT
Pressure transmitter
AI-Pressure
Volume flow
Density
Density compensation coefficient
Temperature
Pressure
<Standard part>Calculation types: 1-10
Massflow
OUT
AI2-Temperature
OUT
(Volume flow x density)
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Mass Flow Calculation in digitalYEWFLO Vortex Flow Meter
Yokogawa Technical Report English Edition Vol.53 No.2 (2010)
transmitters (3). The resources include the physical properties database etc. The DYFMVTool started by the device DTM calculates density based on interactively set data such as the properties of the f luid, calculation standard, pressure and temperature conditions, gas components, etc. The compensation coefficients required for density calculation are eventually downloaded to the instruments. Figure 5 shows examples of DYFMVTool settings and density calculation results.
Figure 4 Configuration of the FieldMate FlowNavigator
Figure 5 Examples of the DYFMVTool Settings and Density Calculation Results Display
Communication device (HART*2, FF*1)
EJX differential pressure/pressure transmitter(multivariable type)
USB port/PCMCIA card slot
digitalYEWFLO
DYFMVTool EJXMVTool
Database Operation manual
DYF(SoftDL) FF*1 DTM
EJX910HART*2/FF*1 DTM
FieldMateFlowNavigator (Flow Configuration Software)
Resources
Programs
Notebook PC
Device DTMCommunication DTM
*1: FF (FOUNDATION Fieldbus) protocol*2: HART (Highway Addressable Remote Transducer) protocol
Table 1 Items of Mass Flow Calculations in the Arithmetic Function Block Calculation items Description
a) Calculation for saturated steam based on temperature Calculates steam density from temperature or pressure based on the equations of IAPWS*1-IF97.b) Calculation for saturated steam based on pressurec) Calculation for superheated steam by
temperature and pressured) Temperature/pressure compensation calculation
for gasCalculates gas density with compensation for temperature/pressure based on Boyle’s Law and Charles’ Law.
e) Temperature compensation calculation for liquid Calculates liquid densities using compensation formulas described in API*2 or JIS*3 (JIS K 2249).f) Temperature/pressure compensation calculation
for gas (polynominal approximate calculation)Calculates density using the polynominal approximation defined in the FlowNavigator. General fluids : Utilizes the physical properties database of DIPPR*4 Natural gas : Complies with standard natural gas calculation specifications AGA*5 No. 8 / ISO*6 12213: 1997 First edition
g) Temperature/pressure compensation calculation for liquid (polynominal approximate calculation)
*1: International Association for the Properties of Water and Steam*2: American Petroleum Institute*3: Japanese Industrial Standard*4: Design Institute of Physical Properties of the American Institute of Chemical Engineers*5: American Gas Association*6: International Organization for Standardization
(a) Fluid-type setup
(b) Natural gas component setup
(c) Density calculation results of natural gas
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Mass Flow Calculation in digitalYEWFLO Vortex Flow Meter
Yokogawa Technical Report English Edition Vol.53 No.2 (2010)
RESULTS OF FIELD TEST
Mass flow tests were conducted at a natural gas test site of Advantica in the UK, which has been certified by the United Kingdom Accreditation Service (UKAS) (4). Figure 6 shows the test results for two different sizes: 50 mm and 150 mm in diameter. Both have been verified to be within the target ranges of mass flow rate accuracy. Figure 7 shows the system configuration used for the testing.
As reference, the mass f low rate was used; the volume f low rate was measured by a UKAS-cer tif ied turbine meter and then the mass f low rate was calculated through compensation of temperature and pressure. As for natural gases, gas components must be measured to compensate the density. Thus, gas components were measured using a gas chromatograph and their values were transmitted to the Advantica's host PC and the DYFMVTool. The DYFMVTool performed calculations based on AGA No. 8, a standard for calculating natural gas densities established by the American Gas Association, and downloaded the density compensation coefficients to the digitalYEWFLO under test. The digitalYEWFLO calculated the density using the downloaded compensation coefficients taking the temperature and pressure into account, and then calculated the mass flow rate by multiplying the volume flow rate measured by digitalYEWFLO by the density.
Figure 6 Results of Mass Flow Tests with Natural Gas
Figure 7 System Configuration of Natural Gas Test Site
CONCLUSION
Combination of the FieldMate FlowNavigator and the FOUNDATION Fieldbus communication type digitalYEWFLO has enabled highly accurate mass f low calculations. In addition, the interactive setup has improved operability. We plan to provide this solution with other protocols than FOUNDATION Fieldbus supported by the FOUNDATION Fieldbus communication type digitalYEWFLOW.
Furthermore, we are continuously enhancing diagnosis-based application software such as impulse line blockage diagnosis, utilizing the FDT/DTM technology. We will continue to create products that contribute to society.
REFERENCES
(1) Hidekazu Wakui, Masami Wada , et a l ., “‘d ig it alYEWFLO multivariable type’ vortex flowmeter with built-in temperature sensor,” Yokogawa Technical Report English Edition, No. 37, 2004, pp. 21-24
(2) Isao Hirooka, Youji Saitou, et al., “FieldMate Field Device Management Tool for the New Era,” Yokogawa Technical Report English Edition, No. 44, 2007, pp. 9-12
(3) Akio Itou, Shin-ichi Mimura, et al., “EJX910 mult ivar iable transmitter,” Yokogawa Technical Report English Edition, No. 42, 2006, pp. 13-16
(4) Shin-ichi Ooki, “Topics on Standards and Applications of Vortex Flow Meters,” The Piping Engineering, Vol. 50, No. 12, 2008, pp. 59-62 in Japanese
* digitalYEWFLO, FieldMate, FlowNavigator, EJX, EJXMVTool are registered trademarks of Yokogawa Electric Corporation.
* FOUNDATION Fieldbus and HART are registered t rademarks of Fieldbus FOUNDATION and HART Communication Foundation (HCF), respectively.
(a) For size of 50-mm in diameter
(b) For size of 150-mm in diameter
-2
-1.5
-1
-0.5
0
0.5
1
1.5
2
200001600012000800040000
Target accuracy
-2
-1.5
-1
-0.5
0
0.5
1
1.5
2
1500001200009000060000300000
Target accuracy
Err
or [%
]
Mass flow rate [kg/h]
Err
or [%
]
Mass flow rate [kg/h]
Q TPTP
JunctionBox
PCFlowNavigator PC for gas
chromatograph
Gas chromatograph
PCAdvantica
Q
Q: Volume flowP: PressureT: Temperature
Gas component setup
DYFvortexflowmeter
EJXpressuretransmitter
YTAtemperaturetransmitter
Analog communication
Measuring equipment of Advantica
Measuring equipment of Yokogawa
FOUNDATION Fieldbuscommunication
Turbinemeter
38100